ES2257396T3 - INK RECEPTORS COATINGS, WATER RESISTANT, FOR PRINTING BY INK JETS, MATERIALS AND METHODS FOR SUCH COATING. - Google Patents

Abstract

Media coatings for use on substrates for ink jet printing include a cationically modified clay, a cationically modified silica and a binder. Alternatively, the media coatings also include additional additives. The ratio of cationically modified clay to cationically modified silica varies in the coating formulation from about 1% to about 99%. Desirably, the ratio of the cationically modified clay to cationically modified silica varies from about 10% to about 50%. More desirably, the ratio of cationically modified clay to cationically modified silica varies from about 25% to about 35%. The ratio of the total cationically modified clay and cationically modified silica to binder varies from about 20% to about 80%. Desirably, the ratio of the total cationically modified clay and cationically modified silica to binder varies from about 65% to about 75%.

Description

Resistant ink receiving coatings to water, for inkjet printing, materials and methods for said coating.

Technical sector to which the invention belongs

The present invention relates to formulations of coatings for paper, laminar elements and others substrates that have the ability to receive water inks applicable by jets and forming images that show a superior quality compared to paper, laminar elements and other substrates susceptible to uncoated printing. From more specifically, the present invention relates to cationically modified coatings that make it resistant to Water printed images. The present invention relates also to methods for coating different substrates susceptible to printing using said coatings and it also refers to materials provided with said coatings.

Background of the invention

The inkjet printing method is a Commercially important and fast printing process expansion because of its ability to produce hard copies in multiple colors, high quality and economy. Actually, the inkjet printing methods are becoming the usual printing methods for producing copies in color of computer generated images consisting of graphics and printed motifs ("fonts") in narrow formats and wide Inkjet printing is a printing method no impact and no contact, in which an electronic signal controls and directs the droplets or a stream or flow of ink that It can be deposited on a wide variety of substrates. The usual inkjet printing technology involves the force the ink droplets through small nozzles by piezoelectric pressure, thermal injection or oscillation, making them pass to the surface of a material / support. Printing by ink jets is very versatile in terms of variety of substrate material that can be treated, and also in terms of print quality and operating speed that can be get. In addition, inkjet printing is controllable digitally

For these reasons, the printing methods by ink jets have been widely adopted for marking and industrial labeling In addition, jet printing methods ink have found a wide field in design application of architecture and engineering, medical imaging, office printing (text and graphics), imaging systems geographical (for example, for seismic data analysis and maps), signage, visualization graphics (for example, photographic reproduction, graphics applicable in the company and in the judicial field, graphic arts) and the like. Finally the inkjet printing has been used today to create an image on a variety of substrates textiles

Dyes and pigments have been used as colorants for said inkjet ink formulations. However, these materials do not always adhere well to the substrates to which the ink is applied. For example, dyes can be dissolved when contact of the printed substrate with water takes place. In addition, images applied using inkjet printing methods may show a tendency to run or stain on repeated contact or may be actually removed from the printed surface if exposed to substantial amounts of aqueous media (for example, if a printed article by ink jets it is exposed to water or establishes contact with water by other means). There is, therefore, a need in this technique to achieve coatings that increase the water resistance capacity of different substrates, in particular when they are to be used on said aqueous-based red substrates. It is to this need that the present invention is directed, since the
Coatings of the present invention have been shown to be especially effective in achieving water resistance.

JP 61 2774841 discloses a print media coating comprising a pigment cationic and / or an amphoteric pigment and a binder. A pigment Preferred cationic is cationic silica. An amphoteric pigment Preference is clay.

Characteristics of the invention.

In accordance with the present invention, the claim 1 discloses coatings for supports of printing for use on substrates for printing by ink jets that include a modified clay cationically, a cationically modified silica and a binder. Print media coatings can also include additional additives. In particular, in a embodiment of the present invention, the coatings for Printing media also include a surfactant. In other embodiment of the present invention the proportion of clay cationically modified with respect to the modified silica cationically varies in the formulation of the coating between the 1% and 99%. Preferably, the proportion of modified clay cationically with respect to cationically modified silica It varies between 10% and 50% approximately. More preferably, the proportion of cationically modified clay with respect to cationically modified silica varies between 25% and 35% approximately. The total proportion of modified clay cationically and cationically modified silica with respect to Binder varies between approximately 20% and 80%. Preferably, the total proportion of modified clay cationically and cationically modified silica with respect to Binder varies between 65% and approximately 75%.

In addition, the present invention discloses a method for carrying out the coating of a substrate of according to claim 18, method comprising the application of a coating, comprising modified silica cationically, a cationically modified clay and a binder, to a substrate.

In addition, the present invention is directed, of according to claim 25, to a substrate provided with a coating comprising a substrate and a coating that comprises cationically modified silica, modified clay cationically and a binder.

These and many other advantages and features of the present invention will be apparent from the following detailed description of the preferred embodiments and of the appended claims.

Detailed description of the invention

In accordance with the present invention, there are water-resistant ink receptive coatings for inkjet printing that includes modified clay cationically, cationically modified silica and a binder. These formulations use a mixture of cationic clay and cationic silica in combination with one or more binders, and of optionally, surfactants and other additives, to produce a superior image quality and water resistance.

The coating formulations can be used with paper, laminar elements, gauze and other substrates usual printable ones that are ink receivers to water for jet printing and form images showing a superior quality with respect to paper, laminar elements or others uncoated substrates or substrates that have only been coated with cationically modified clay or silica cationically modified. Preferred substrates for use with the coating of the present invention include laminar elements known as synthetic papers such as available from Oji Yuka Synthetic Paper Corporation and marketed by Kimberly-Clark under the trade name Kimdura®. These substrates result preferred for reasons of water resistance, since they They don't swell or twitch. In particular, it can be used from Easy shape Kimdura® synthetic paper, which has a thickness of 150 µm. Other materials can also be easily used Kimdura® with a thickness between approximately 60 and 500 µm. Is important that these substrates can be fed in a way simple through an inkjet printer.

Other laminar elements that can be provided with the coating of the present invention include films of polyester and vinyl. Other substrates that can be endowed with the coating of the present invention include substrates of saturated latex paper. In addition, said coatings also they can be applied to nonwoven substrates, such as made from polyolefins, and also to substrates tissues.

The images printed on the coating for inkjet printing media are equipped with water resistance capacity, thus resisting the Image deterioration in repeated exposures to water. Bliss Quality can be developed in a matter of hours or minutes counting from the end of printing. The exhibition to water can be achieved by placing the printed sample under water current or in the form of drops, or even submerging said sample in water for a limited period of time.

As explained above, the coating formulation in the present invention uses a combination of cationically modified clay and silica cationically modified. An example of said modified clay cationically it can be obtained from ECC International of Atlanta, Georgia, under the trade name Astra-Jet ™. Said modified clay cationically it consists of an aqueous dispersion of kaolin and a polyquaternary amine. Although ECCI markets a line of Astra-Clay? clays, the composition of original clay is desirable for the realization of coating of the present invention.

The cationically modified silica may consist of an aqueous dispersion of silica including a cationic polymer similar to that described above. Alternatively, the cationic silica may consist of an aqueous amorphous silica stabilized with alumina and other additives, such as the cationic silica gel dispersion sold by Grace Davison of Columbia, Maryland, under the trade name Cationic Sylojet P612, with a modifier cationic surface. Grace Davison markets unmodified silica under the trade name Sylojet
P612.

The proportion of modified clay cationically with respect to cationically modified silica may vary in the coating formulation between 1% and the 99% by weight. Preferably, the proportion of modified clay cationically with respect to cationically modified silica It can vary between 10% and 50% by weight approximately. From even more preferably, the proportion of modified clay cationically with respect to cationically modified silica It can vary between 25% and 35% by weight approximately.

The formulation additionally includes a binder. Said binder serves to bind the clay and the silica (pigment particles), and also to bind the coating to a printing substrate. Said binder can be composed of any water insoluble polymer, forming of film, provided that the polymer is compatible with clay cationic and cationic silica. The binders that are Appropriate for the formulation of the present invention include, but without limitation, non-ionic latex types composed of polymers of vinyl acetate, vinyl ethylene acetate, acrylates, and vinyl acrylate acetate. Other polymeric materials which are suitable as binders include styrenic products such as styrene gums (SBR), styrene anhydride maleic (SMA) and styrene acrylonitrile (SAN). They can also Cationic latex types are used as appropriate binders. In addition, latex types can also be used as binders slightly anionic Mixtures of the binding agents mentioned in claim 7. The types of strongly anionic latexes would be unacceptable as binders, since they would coagulate with the remaining materials cationic The total proportion of pigment, which is the combination of cationically modified clay and modified silica cationically, with respect to the binder may vary between the 20% and 80% approximately. Preferably, the total proportion of pigment with respect to the coating binder can vary between 65% and approximately 75%.

In addition to clay, silica and binder, optional additives can be added to improve the performance of the coatings For example, stabilizers of light / UV light absorbing agents to improve resistance to light. In addition, surfactants or moisturizers Preferably, in the case of using said The surfactants are non-ionic, cationic or Zwitterionic Examples of such surfactants include Triton X100 and Tergitol of Union Carbide. In addition, a leveling agent such as an aliphatic diol. Other additives optional include flow modifying agents, and brighteners and / or optical brighteners.

The present invention will be described at continued by examples. These examples, however, do not they should be considered as limiters of any kind of scope of the present invention. Unless determined otherwise, All percentages are percentages by weight. An example of a coating formulation of the present invention, for the use in a variety of printing substrates, it is shown in Table 1. An example of a coating formulation of control, without cationically modified silica, is described in the Table 2. The particle size of Sylojet silica materials P612 is approximately 12 µm. The clay and silica are present in aqueous dispersions.

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TABLE 1 Example of modified clay coating cationically and cationically modified silica of the present invention

(Sample identified as "A" coating for testing) Ingredient % from solids Dry Parts Wet Parts % in weigh % in weigh Load wet dry damp x 1.5 Water 0.0 0.0 0.0 0.0 0.0 Silica cationic 29.4 53.0 180.3 52.4 18.2 270.4 Sylojet P612 a Clay Astrajet 35.2 22.5 63.9 22.3 7.7 95.9 Q2 5211 100.0 0.6 0.6 0.6 0.21 0.9 Airflex 540 54.8 25.0 45.6 24.7 8.6 68.4 Total 101.1 290.4 435.6 Notes: to. Cationic silica Sylojet P612 is modified silica cationically

For the purpose of the coating described previously, Q2 5211 is a polysiloxane surfactant ethoxylated and was obtained from Dow Corning. The Airflex 540 is a latex bond of vinyl ethylene acetate (EVA) available from Air Products. The proportion of pigment with respect to binder (P / B) for the sample was 0.75: 1, and the percentage Total solids (% TS) was 34.8% by weight.

TABLE 2 Example of modified clay coating cationically and silica without modification of the present invention

(Sample identified as "C" coating for testing) Ingredient % from solids Dry Parts Wet Parts % in weigh % in weigh Load wet dry damp x 1.5 Water 0.0 0.0 0.0 0.0 0.0 Silica Sylojet 26.7 53.0 198.5 52.4 17.2 297.8 P612 a Clay Astrajet 35.2 22.5 63.9 22.3 7.3 95.9 Q2 5211 100.0 0.6 0.6 0.6 0.19 0.9 Airflex 540 54.8 25.0 45.6 24.7 8.1 68.4 Total 101.1 308.6 463.0 Notes: to. Sylojet P612 silica is modified silica of non-cationic form

The proportion of pigment relative to binder (P / B) for the sample was 0.75: 1, and the total percentage of solids (% TS) was 32.8% by weight.

Extraction

In general, for each of the coatings of the examples, the components were combined in the order shown using a plastic beaker and A paddle mixer. Extractions were carried out using the Meyer rod method (known to technicians in the matter) with a Meyer # 28-30 rod in Kimdura® FPG 150 (for 150 µm) available from Kimberly-Clark, to produce a layer weight of 20 g / m2 at 23 g / m2. 25.4 coated sample sheets cm by 30.5 cm (10 by 12 inches) were cut to a size of 21.6 cm by 27.9 cm (8.5 by 11 inches) to facilitate Printing and testing.

The specific extraction procedure Used was as described below. A sheet was placed 10 by 12 inch paper or sheet (for example Kimdura® FPG 150) on a flat surface. A rod (Meyer) was placed with wound on the top of the sheet and weights of 2 were placed kg at the ends of the rod to prevent slippage. He coating material was poured into the substrate so that produced the contraction of the rod and formed an accumulation narrow with the width of the substrate. The substrate was stretched under the rod and the coating was spread evenly along the blade. It must be recognized that they can be obtained different coating weights using winding rods with Different sizes of metallic wire.

Coatings can also be applied alternatives in the substrates by other methods of coating known to those skilled in the art, as per example the methods of coating by means of jet blade air ("Air Knife") or by the "Slot Dye" method. Others coating methods include coating methods by rotogravure roller, and roller coating invested. Coatings can be applied with levels between 5 and 45 grams per square meter (gm -2). Preferably, the coatings are applied with levels between 15 and 35 gm -2 approximately. So, the samples were placed in a forced air convection oven at 75 ° C for 3-5 minutes approximately to allow drying of these samples. The samples were stored in conditions at room temperature (20-25ºC) overnight before printing.

The already dried samples were printed with the printers and settings indicated in Tables 3-5 shown below.

Print

Cyan blocks (C) were printed, magenta (M), yellow (Y), black (B), red (R), green (G) and blue (B) from the block pattern of the "Paint" application of Microsoft® MS in a pattern of 5.1 cm by 12.7 cm (2 x 5 inches) on Kimdura® sheets. The color blocks were printed with inks supplied by each printer. If you also included a blank block (not printed) in the pattern of 5.1 cm by 12.7 cm (2 x 5 inches). The printers used included a printer Hewlett-Packard 722C with HP Premium Ink Jet settings Paper / Best Settings, an Epson 850 with Photo Quality Ink settings Jet Paper / 720 dots / 2.54cm / Automatic Settings and a Canon printer 4200 with Hi Resolution Paper / Standard / No Color Matching settings Settings Following printing, the samples were dried overnight at room temperature conditions before carrying out additional tests. Following the printing and drying, the samples were cut into patterns of 5.1 cm by 12.7 cm (2 x 5 inches) block.

Soaking tests

Samples cut from 5.1 cm by 12.7 cm (2 x 5 inches) were placed in 2 liter plastic containers containing 2 liters of deionized water at 20 ° C for 24 hours. The samples were fixed to the side of the container so that the entire test pattern remained submerged throughout the entire proof. Once that period had elapsed, the samples were removed from the container and placed flat on cloths KimWipes® absorbents. KimWipes are absorbent cloths available at from Kimberly-Clark Corporation. The sample surfaces were dried gently with said KimWipe® cloths. The samples were allowed to dry completely before spectral measurements were taken (2-3 minimum hours). A spectrodensitometer was used X-Rite® Model 938 to carry out measurements spectral L * a * b, the CIE LAB measurement used by The technicians in the field. The spectrodensitometer X-Rite was acquired from X-Rite Corporation of Grandville, Michigan. During the realization of the measurements, the type of illuminant was D 50 and the observer of 2nd.

The resulting degree of optical clearance (transparency) of water exposure was measured quantitative using the values L * a * b. Delta E * is calculated according to the following equation:

ΔE * = SQRT [(L * standard - L * sample) 2 + (a * standard - a * sample) 2 + (b * standard - b * sample) 2],

in which the standard values are representative of the values of the sample that has not been put in soaking.

The higher the DeltaE * (later designated \ DeltaE *), the greater the change in the intensity of the color. A large increase in deltaE * is indicative of attenuation, washing or bleeding of the ink. During the test L * a * b * in the samples, controls of each coating were used as base of comparison. Control samples (STD) were printed only with the respective formulations, unlike those that were printed and soaked. The biggest bleeding of the inks was recorded when silica was used without modification in the samples tested, that is, formulation "C".

TABLE 3 Printer results for the printer Hewlett-Packard 722

Sample # Covering Printer Mode Print Color ΔE * 24 hours. Soaking ΔE * average one TO HP 722 HP Prem. IJ Paper / Best K 0.19 W 2.81 B 4.37 C 8.36 G 16.11 Y 14.31 R 2.9 M 0.74 6.22 2 C HP 722 HP Prem. IJ Paper / Best K 0.23 W 7.40 B 22.82 C 11.72 G 12.78 Y 24.71 R 6.49 M 6.58 11.59

TABLE 4 Print results for Canon printer 4200

Sample # Covering Printer Mode Print Color ΔE * 24 hours. Soaking ΔE * average 3 TO Canyon Hi Beef. Paper / K 2.94 4200 Standard W 0.43 B 2.41 C 1.33 G 5.37 Y 3.25 R 2.36 M 3.09 2.65 4 C Canyon Hi Beef. Paper / K 1.18 4200 Standard W 0.39 B 3.82 C 2.63 G 3.39 Y 5.58 R 2.27 M 7.3 3.32

TABLE 5 Print results for Epson printer 850

Sample # Covering Printer Mode Print Color ΔE * 24 hours. Soaking ΔE * average 5 TO Epson 850 Photo Qual IJ K 2.41 Paper / 720 dpi W 0.66 B 5.44 C 4.79 G 3.48 Y 3.92 R 1.25 M 1.81 2.97 6 C Epson 850 Photo Qual IJ K 3.17 Paper / 720 dpi W 0.84 B 18.42 C 4.03 G 11.15 Y 4.18 R 18.58 M 7.87 8.53

From the data in the tables you can see that the use of a coating that includes a clay cationically charged and a cationically charged silica (coating A) improves the water resistance of an image printed by ink jets on a coated substrate, such as is shown by the measurements made by a Spectrumdensitometer For example, looking at the results of the Epson 850 printer, the ΔE * values of the red color for the control (coating C) compared to the combination of cationic clay / silica (coating A) demonstrate a significant difference in terms of water resistance.

Although the present invention has been described in detail with particular reference to a preferred embodiment thereof, it should be understood that it can suffer numerous modifications, additions or omissions without leaving of the scope of the invention as indicated in the attached claims.

Claims (40)

1. Coating for print media that shows water resistance after jet printing of ink, whose coating for print media comprises: cationically modified silica; cationically modified clay; Y a binder. 2. Coating for print media, according to claim 1, wherein the modified clay cationically it comprises an aqueous dispersion of kaolin and a polyquaternary amine. 3. Coating for print media, according to claim 1, wherein the modified silica cationically comprises an aqueous dispersion of silica including A polyquaternary amine. 4. Coating for print media, according to claim 1, wherein the modified silica cationically comprises an amorphous aqueous silica stabilized with alumina. 5. Coating for print media, according to claim 4, further comprising a modifier cationic surface. 6. Coating for print media, according to claim 1, wherein the binder comprises a water-forming film-forming polymer, which is compatible with cationic clay and cationic silica. 7. Coating for print media, according to claim 6, wherein the binder is selected among the group consisting of nonionic latexes comprising polymers of vinyl acetate, vinyl ethylene acetate, acrylates, vinyl acrylate acetate; styrenic products comprising styrene gums (SBR), styrene anhydride maleic (SMA) and styrene acrylonitrile (SAN); cationic latex; soft anionic latex; and mixtures thereof. 8. Coating for print media, according to claim 7, wherein the weight ratio of the Clay with respect to silica is between 1% and 99%. 9. Coating for print media, according to claim 8, wherein the weight ratio of the clay with respect to silica is between 10% and fifty%. 10. Coating for print media, according to claim 9, wherein the weight ratio of the clay with respect to silica is between 25% and 35% 11. Coating for print media, according to claim 1, wherein the proportion of total weight of clay and silica with respect to the binder is comprised between 20% and 80%. 12. Coating for print media, according to claim 11, wherein the proportion of total weight of clay and silica with respect to the binder is comprised between 65% and 75%. 13. Coating for print media, according to claim 1, further comprising at least one material selected from the group consisting of agents light stabilizers / UV light absorbers, surfactants, wetting agents, leveling agents, flow modifiers, optical brighteners and brighteners. 14. Coating for print media, according to claim 13, which comprises a surfactant selected from the group consisting of non-surfactants ionic, cationic and zwitterionic. 15. Cover for printing media according to claim 13, wherein said coating for print media comprises a leveling agent, wherein said leveling agent comprises an aliphatic diol
co. 16. Coating for print media, according to claim 1, wherein the cationically modified clay comprises an aqueous dispersion of kaolin and an amine polyquaternary and cationically modified silica comprises a aqueous silica dispersion that includes an amine Polyquaternary 17. Coating for print media, according to claim 1, wherein the cationically modified clay it comprises a dispersion of kaolin and a polyquaternary amine and the cationically modified silica comprises an amorphous aqueous silica stabilized with alumina. 18. Method of coating a substrate that comprises the application to a substrate of a coating that comprises cationically modified silica, a modified clay cationically and a binder. 19. Method of coating a substrate, according to claim 18, wherein said substrate is selected from the group consisting of paper, elements laminar and gauze. 20. Method of coating a substrate, according to claim 19, wherein the paper comprises paper synthetic that can be fed through a printer by ink jets 21. Method of coating a substrate, according to claim 20, wherein the synthetic paper has a thickness from 60 to 500 µm. 22. Method of coating a substrate, according to claim 21, wherein the synthetic paper has a 150 µm thick. 23. Method of coating a substrate, according to claim 19, wherein the substrate comprises a material selected from the group consisting of a substrate nonwoven, a woven substrate, a polyester film, a Vinyl film and saturated latex paper. 24. Method of coating a substrate, according to claim 23, wherein the substrate comprises a nonwoven substrate comprising a polyolefin. 25. Substrate with coating that comprises a substrate and a coating containing silica cationically modified; cationically modified clay; and a binder. 26. Substrate with coating, according to claim 25, wherein the cationically modified clay comprises an aqueous dispersion of kaolin and an amine Polyquaternary 27. Substrate with coating, according to claim 25, wherein the cationically modified silica comprises an aqueous dispersion of silica that includes an amine Polyquaternary 28. Substrate with coating, according to claim 25, wherein the cationically modified silica it comprises an aqueous amorphous silica stabilized with alumina. 29. Substrate with coating, according to claim 25, wherein the binder comprises a polymer non-water soluble film former, which is compatible with a cationic clay and cationic silica. 30. Substrate with coating, according to claim 29, wherein the binder is selected to from the group consisting of non-ionic latex types that they comprise polymers of vinyl acetate, vinyl ethylene acetate,  acrylates, vinyl acrylate acetate; styrenic products comprising styrene gums (SBR), styrene anhydride maleic (SMA) and styrene acrylonitrile (SAN); cationic latex; soft anionic latex; and mixtures thereof. 31. Substrate with coating, according to claim 25, wherein the proportion of clay weight with with respect to silica it is between 1% and 99%. 32. Substrate with coating, according to claim 31, wherein the proportion of clay weight with with respect to silica it is between 10% and 50%. 33. Coated substrate, according to claim 32, wherein the clay weight ratio with respect to silica it is between 25% and 35%. 34. Coated substrate, according to claim 25, wherein the proportion of total clay weight and silica with respect to the binder is between 20% and 80% 35. Substrate with coating, according to claim 34, wherein the proportion of total clay weight and silica with respect to the binder is between 65% and 75% 36. Substrate with coating, according to claim 25, further comprising at least one material selected from the group consisting of agents light stabilizers / UV light absorbers, surfactants, wetting agents, leveling agents, flow modifiers, optical brighteners and brighteners. 37. Substrate with coating, according to claim 36, comprising a surfactant selected from from the group consisting of nonionic, cationic surfactants and zwitterionic. 38. Coated substrate, in accordance with claim 36, wherein the support coating printing comprises a leveling agent, wherein said agent leveler comprises an aliphatic diol. 39. Coated substrate, according to claim 25, wherein the cationically modified clay comprises an aqueous dispersion of kaolin and an amine polyquaternary and cationically modified silica comprises a aqueous silica dispersion that includes an amine Polyquaternary 40. Substrate with coating, according to claim 25, wherein the cationically modified clay comprises an aqueous dispersion of kaolin and an amine polyquaternary and cationically modified silica comprises aqueous amorphous silica stabilized with alumina.